• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    For use with an adjustable speed a-c electric motor having a stator adapted to be coupled to a source of variable frequency excitation and a rotor in which torque is developed when the motor is excited, the strength of said torque being dependent on interacting current and flux in the motor, a scheme is provided that comprises means for deriving an angle feedback signal representative of the actual phase angle between the aforesaid current and flux and means responsive to said angle feedback signal for controlling the source of variable frequency excitation so as to control the frequency of stator excitation as a function of the angle feedback signal.
    公开号:SU1371513A3
    申请号:SU772533349
    申请日:1977-10-03
    公开日:1988-01-30
    发明作者:Дуглас Дъатре Джон;Энтони Лайпо Томас;Барр Планкетт Аллан
    申请人:Дженерал Электрик Компани (Фирма);
    IPC主号:
    专利说明:

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    U1
    00

    SP
     13
    The invention relates to electrical engineering, in particular, to control by electric drives based on an induction motor.
    The purpose of the invention is to step up the stabilization of the rotational speed in a wide range of rotational frequency, load and temperature.
    The drawing shows a structural diagram of an AC drive.
    The AC drive contains an asynchronous motor 1 connected to the output of a current inverter 2, the input of which is connected via a choke 3 to a voltage regulator 4, a voltage regulating channel composed of series-connected voltage regulator control unit 5, proportional-integral regulator current torus 6, comparator block 7, one in which is connected to the current sensor 8 of the induction motor, and the other to current setting 9, the input of which is connected to the output 10 of the job of the task shaping unit II Moment and flow. The frequency control channel of the electrical alternating current i consists of block 2 control 1 invertor of unit 3 sum, the frequency controller 14 slid, reference 15, while the output of block 2 controls the inverter NIN with inverter 2 and the input g: odncl) A unit is added to the summation unit 13, the first input of which is connected to the tachogenerator Ib, and the & t input is connected to the slider frequency controller. The first input of the frequency regulation channel block 15 is often connected to the output 7 of the torque setting of the torque and flow setting unit 1I, and the second input to the output of the torque calculation section 13, one input of which is connected to sensors 19 of the motor phase currents, the output of the tacho generator 16 is connected with the input of the moment setting and the flow setting unit 11 to which the rotation speed setting output 20 is connected,
    An angle calculator 21 between the current and flow vectors with three inputs was inserted into the electric drive, 22-2 integration blocks, the measuring coil 25-27 are located in the air gap of the engine, the frequency is additionally entered into the adjustable channel.
    0
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    the second comparison unit 28, the angle picker 2 between the current and flow vectors, while the second input of the torque calculation unit 18 is connected to the first input of the 21 B1 unit. the angle between the current and flow vectors and the outputs of the integration blocks 22-23, the inputs of which are connected to the outputs of the catches 25-27, the output of the torque calculator 18 is connected to the second input of the angle calculator 21 between the current and flow lecturers, the third input is connected to sensors 9 phase currents, and the output is connected to the first input of the second block 2B of the frequency control channel, the second input of which is connected through the angle control 19 between the current and flow vectors to the output of the first block 15 of the frequency control channel. The output of the second unit of comparison of this control channel through the slip frequency controller 14 is connected to the first input of the summation unit 13.
    In another embodiment, the AC drive current to the can; In the frequency control, the integrated amplifier 30 and the third comparison unit 31 are introduced, while the depth of contact I1 ts is grains 1 of the amplifier 30 underg. Tutchey to the output is on the comparator block 28, and the output to the HepBONfv input is trust,:; / o block 3 is compared to the adjusted control channel, the third input of the third comparator block is connected to the frequency regulator 14, j, which is connected to the first entry of Olok 13 summation.
    Blocks 5–9 make up the voltage control loop, which makes Boz dan 2 the stator of the motor 1 by adjusting the average values -,: the voltage Vj, which, in turn, determines the amount of current to the inductor 3, and “Successively, the amplitude of the main gok in the stator windings reduces the error of setting the excitation to the data from sensor 8. and change this signal with the signal from yes: riKa 9 to.ta. This circuit is represented by 1i: .. t ..: g.oRg y control circuit, in which. M with | ial reverse saint And and ks Mand-: ь, G; Ignal sravnivakg; i; in block 7 ;; mm droning V (. dacha on the sigka.a error, reflecting the mismatch me; kdu nsh-1I. The signal error1t processes 6 tokp in the controller, it has: |; tegralnui and l.churtsionalnuyu
    313
    transient characteristics, which ensures the receipt of a zero statistical error. From the current regulator 6, a compensated signal V is received and fed to the corresponding inputs of the control unit 5 of the controller 4 in the controller. Thus, the voltage control loop responds to any error between the feedback signal by the magnitude of the excitation, ensuring that V changes in cm 11 after correction, which increases or decreases the main current amplitude and stator windings and decreases the error value to zero. The feedback signal of the magnitude of the excitation serves to express the actual level of excitation in the stator two gel 1. Thus, it can be a measure of the average value of the actual magnetic flux induced in the gap between the stator and the rotor of the engine 1 when it is excited and at the same time Feedback signal is preferred to be obtained from magnetic flux feedback signals. The command signal of the current setting device 9 is obtained from the control signal F
    representing the three axis) leads to the excitation of the stator, as determined by the unit 11 of the formation of the moment and the P of it,:.
    The second external circuit adjusts the motor torque by adjusting the basic switching frequency 1; and the inverter 2 current. This frequency determines the main frequency of the current in the stator windings, which minimizes the mismatch between the signal; -;,; - the breakdown of feedback T for torque torque block 18 and the variable command signal T (representing engine torque) from output 17 of block 1 1. The circuit contains a comparison unit 15, in which the feedback signal 1 of the command signal is compared with the output of an error signal, which reflects the error between them, CHrHajT errors are processed in the unit 29, which has an integral: proportional and transient response, which provides a zero statistical error. The gauge 29 provides to the command sin b for the internal C7: 1 bea iz. :: .- ing contour. This signal is a function of the control signal providing a reduction;
    , with p 5
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    13
    Dispel errors between T and T to zero. This signal is summed up in the summation unit 13 with the QP feedback signal for outputting the excitation frequency control signal cOg, representing their algebraic sum. The feedback signal on the speed CO is supplied by appropriate means, for example, tachogenerator 16, to sense the actual angular velocity of the rotor of the engine 1. The excitation frequency control signal COj is supplied to the corresponding inputs of the control unit 12 of the current inverter 2.
    Since the value of CO corresponds to the excitation frequency of the stator, and the value U. corresponds to the equivalent frequency of the actual motor speed, the signal at the input of the summation unit 13 represents the slip frequency of the motor Oj-
    Thus, the external control loop is sensitive to any mismatch between the feedback signal T but the torque determined by block 18 and C1 is driven by the control1
    TI on BI is running 17 block 1 1 to provide a change (and the switching frequency of the switching elements of the inverter in a corrective sense and increase or decrease the frequency of the excitation) 1 and the stator to reduce the magnitude of the error; 1 and to zero.
    A control signal; T, for example, is provided by a torque and flow setting unit 11 and its value is determined in accordance with a design program that provides the engine with the required speed and torque characteristics (usually block 1 is designed to match the control value of the signal 0c to the signal value control T). The feedback signal for torque T of unit 18 serves to represent the actual magnitude and relative direction of the torque of the rotor of the engine 1 when excited. It can be obtained from the engine by any means, for example, multi-turn measuring coils 25, 26 and 27, located close to and sensitive to the actual magnetic flux induced in the gap between the stator and the rotor of the engine 1 when excited by a star, resulting in each coil
    It has voltage signals induced by D proportional to the rate of change of the magnetic flux in the adjacent part of the gap between the stator and the rotor. In addition, integrating circuits 22, 23 and 24, respectively, are connected to said sensing coils for outputting feedback signals, which are integral over time of the induced voltage signals, thus ensuring that flow feedback signals are correctly represented as quantities and the phase of the actual magnetic flux in the gap between the stator and the rotor. Preferably, the coils 25, 26, 27 are positioned around the gap between the rotor and the stator in combination with the centers of the flow zones belonging to the main cores of the respective phases A B and C of the stator windings. With this arrangement, the feedback signals on the flow, produced by integrators 22, 23, 24, are sensitive to the actual magnetic flux, are represented as VMB V / MC Each of these signals is a variable quantity, having a wave form (sinusoidal), and frequency, which is equal to the main frequency of the magnetomotive force (MDS).
    Signals 4 tt,, "" tegrator-ppv 22, 23 and 24 and phase current signals from sensors 19 phase currents are converted by known expressions into vector quantities with the calculation of the moment in block 18.
    The stability of the engine excitation system under varying load conditions increases. To improve the quality of the transient process, an integrated amplifier 30 and a comparison unit 31 are provided, which are used to control the excitation of the engine as a function of the actual angle b between the axes of the magnetic fields of the stator and the rotor in the machine in a transient mode. By angle P, it is meant the phase angle between two vectors, which represent respectively the magnetic flux and the currents that interact in the motor to create an output torque. This angle is positive in the motor mode in the forward direction and negative in the braking mode in the opposite direction.
    136
    Thus, the magnitude of the slip frequency signal is a function. - days of mismatch between the command; ,, - signal by the angle and feedback signal. The frequency of the current exciting the stator windings of the motor is determined by the main switching frequency of the keys in inverter 2, and changes in this frequency will shift the stator conductivity intervals, and hence the relative phase position of the current vector Ig. As the excitation frequency increases, the stator voltage vector moves in phase (i.e., the angle of this vector increases relative to the predetermined initial position). Suppose that the magnitude of the control signal at the required torque has drastically decreased by a predetermined amount from the point of the steady-state motor mode with the calculated load. This causes a sharp decrease in the command signal sin & T by the angle and corresponding to an increment in the error signal by angle in block 28, which, in turn, is reflected by an ionic decrease in the magnitude of the signal to the slip frequency at the input of block 13, and accordingly control signal sd in frequency and excitations. The startup control unit 2 of the inverter 2 responds to the decrease by reducing the inverter switching frequency, as a result of which the main stator driving frequency is increased. This reduces the slip frequency of the engine, which delays the angular position of the stator current vector relative to. relative to the vector of the magnetic flux in the gap between the stator and the rotopog; (i.e. decreases the angle 0). As a result, both the feedback signal on a spin 1-1 moment in block 18, and the feedback signal on a corner of block 21 decreases — its value and the main frequency of the exciter and stator beat; inside the iopoy working wheelbarrow, where I have; ;; the signal has a reciprocal of the actual torque and the magnitude of the torque set by the reduced command signal T in the incompetent steer control, and there is : between valid feedback signal
    SVYA by UT LU and the new Velich; :; The CC signal of the corner angle in the extrinsic cTa6iLitr contour is no more than the minimum of the mismatch — Br1} 1ne.
    For a stepwise step E in the root of angle 9 in 1d.), The contour responds to the case of the optical signal OpiTHoi i with respect to the angle (as a result of anomalies or possible of various types in the engine or in its load by means of a corrective correction in the stator excitation, which ensures the immediate restoration of the correct angle. This prevents the occurrence of undamped} light in relation to the operating point at the established COCTOHHI -; I. Thus, the actual angular current position vector stat The system spontaneously makes a sequence of komapdn1. at the required angle siiiP, the system becomes asynchronous 1 ru1. The effect of the adjustable angle 0 by the internal circuit can synchronize the starting signals. of inverter 2 (i.e. real m, l mm / current tatsii: the magnetic flux in the gap between st .-: torus and iortor, i.e. tedovatsion - i; :: 1troti: 31- elektrrilG.RRne, that the resultant instability of the oscillating ty.
    The settlement is described by the syst .--. ci.j-bi-lizachchi stabilizes the frequency of the excitation of the trigger in the angle angle, simplifies the requirements with respect to the adjustable source 4 for supplying a constant gok that only the control of the setting is used; In addition, the angle control is expressed in a less disordered current flow in jiuTaHim of the alternating current of inverter 2, in which case the power of the smoothing filter 3 and the parameters of the smoothing filter are significantly more pronounced. The current in the circuit is controlled by the 1P K1 current. The effect of the switching delay and the wrench is weakened by the amplification of the t: angle control loop, which results in the elimination of normal voltage:. commutation conditions inertoo.;.
    1 a :: ignorer 16 not vg:} 1 non-detour1 {me m to satisfy: lbth-6o; bi:.,:; with us. Tabili
    five
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    five
    : -; n do not use. The tachogenerator is switched on to control the speed of the engine by the control system in case of initial application of electric power tsa of the stator winding 1F1G; 1B of the G-kenya rotor or if the opera- tor, 1-p provides for changes in speed, oh. ; if there is no feedback on the actual speed of the engine, the regulating angle of the contour will issue a command of the excitation frequency, which is necessary to minimize the error between the real and the desired values of the angle 9.
    权利要求:
    Claims (2)
    [1]
    1. An AC electric drive containing an asynchronous motor connected to the output of a current inverter, whose input through a choke is connected to a voltage regulator, a voltage regulating channel composed of a 1x serially connected voltage regulator control unit, proportional-integral regulator the current torus, the comparator unit, the din input of which is connected to the current sensor of the xinghong motor, and the other — e. current current; the input of the coematic coezyine with the output of the otog, b :: ok of the formation of the assignment MOMi HTa and noioi; adjusting the frequency - ;, composed of an inverter control unit, summing unit, the frequency controller torus sliding b.choka, the output of the inverter control unit is connected to. a current inverter, the input is connected to a block with a 7-1 myropy} and, the first input of which is connected to the tachogenerator and the second is connected to the slip frequency controller, the first input of the frequency control channel equalizing unit is connected to the output of the torque setting unit and the flow, and the second input - with the output of the moment calculating unit, one input of which is connected to the sensors of the phase currents of the engine, the output of the tachogenerator is connected to the input of the moment setting and flow setting unit to which the output of the setting unit you rotation, characterized in that, in order to increase the rotation frequency stabilization of a wide range of PNP V changes
    91
    rotational speed, load and temperature, an angle calculation unit between the current and flow vectors with three inputs, integration units, measuring coils located in the air gap of an induction motor, a second comparison unit, the angle adjuster between the current and flow vectors are added to the frequency control channel , while the second input of the moment calculator is connected to the first input of the angle calculator between the current vectors and jioTOKa and the outputs of the integration blocks, whose inputs are connected to the terminals, measure nk coils, calculating the time output unit connected to the second input of the calculating block of the angle between current and flux, and the third input of which is connected to the sensors of the phase currents, and an output connected to a first input of the second comparator block channel
    13 o
    frequency control, the second input of which through the angle sensor between the current and flow vectors is connected to the output of the first frequency control channel comparison unit, the output of the second comparison module of this control channel is connected to the first input of the summation unit through the frequency controller of the slip.
    [2]
    2. The electric drive according to item I, which is based on the fact that an integrated amplifier and a third comparison unit are inserted into the frequency control channel, the input of the integrated amplifier connected to the output of the second comparison unit, and the output to the first input of the third comparison unit the specified control channel, the second input of the third comparison unit is connected to the slip frequency controller, and the output is connected to the first input of the summation unit.
    类似技术:
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    SU1371513A3|1988-01-30|A.c.electric drive
    Kirschen et al.1987|Optimal efficiency control of an induction motor drive
    US6166514A|2000-12-26|Apparatus and method for controlling induction motor
    EP0535281B1|1997-02-12|Apparatus for a universal field oriented controller for an induction machine
    US4814678A|1989-03-21|Speed control apparatus for motor
    JPH10243699A|1998-09-11|Synchronous motor controller
    US4453116A|1984-06-05|Scalar decoupled control for an induction machine using current control
    US4314190A|1982-02-02|Controlled current inverter with angle command limit
    US5196778A|1993-03-23|Control apparatus suitable for use in induction motor
    US4001660A|1977-01-04|Regulating the torque of an induction motor
    JP3183516B2|2001-07-09|A method for determining stator flux estimates for asynchronous machines.
    RU2317632C1|2008-02-20|System for vector control of speed of asynchronous electric motor
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    SU1275731A1|1986-12-07|Control device for induction electric motor
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    SU543120A1|1977-01-15|Device for controlling electric power installation of alternating current
    SU1101982A2|1984-07-07|Device for adjusting and stabilizing speed of linear asynchronous motor
    RU1791952C|1993-01-30|Device for control over asynchronous electric motor
    CA1058695A|1979-07-17|Regulating the torque of an induction motor
    JPH08191572A|1996-07-23|Output voltage controlling method of inverter circuit
    同族专利:
    公开号 | 公开日
    FR2366740B1|1984-01-27|
    AU2930777A|1979-04-12|
    ZA774670B|1979-03-28|
    IT1087753B|1985-06-04|
    CA1083663A|1980-08-12|
    JPS5363518A|1978-06-07|
    BR7706571A|1978-08-22|
    AU512880B2|1980-10-30|
    DE2744319A1|1978-04-13|
    US4088934A|1978-05-09|
    ES462768A1|1978-05-16|
    JPS5820234B2|1983-04-22|
    SE7711023L|1978-04-05|
    SE426897B|1983-02-14|
    MX144491A|1981-10-20|
    FR2366740A1|1978-04-28|
    DE2744319C2|1987-08-20|
    GB1587211A|1981-04-01|
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    申请号 | 申请日 | 专利标题
    US05/729,042|US4088934A|1976-10-04|1976-10-04|Means for stabilizing an a-c electric motor drive system|
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